If you’re looking to use Realm from Objective‑C, or from mixed Objective‑C & Swift apps, please see Realm Objective‑C instead. The Realm Objective‑C and Realm Swift APIs are not interoperable and using them together is not supported.

Realm Swift enables you to efficiently write your app’s model layer in a safe, persisted and fast way. Here’s what it looks like:

// Define your models like regular Swift classesclassDog:Object{dynamicvarname=""dynamicvarage=0}classPerson:Object{dynamicvarname=""dynamicvarpicture:NSData?=nil// optionals supportedletdogs=List<Dog>()}// Use them like regular Swift objectsletmyDog=Dog()myDog.name="Rex"myDog.age=1print("name of dog: \(myDog.name)")// Get the default Realmletrealm=try!Realm()// Query Realm for all dogs less than 2 years oldletpuppies=realm.objects(Dog.self).filter("age < 2")puppies.count// => 0 because no dogs have been added to the Realm yet// Persist your data easilytry!realm.write{realm.add(myDog)}// Queries are updated in realtimepuppies.count// => 1// Query and update from any threadDispatchQueue(label:"background").async{autoreleasepool{letrealm=try!Realm()lettheDog=realm.objects(Dog.self).filter("age == 1").firsttry!realm.write{theDog!.age=3}}}

If you have an app that is presently using Core Data and have been considering switching to Realm, we recently published an article discussing how to go about doing this. Go check it out!

Installation

Go to your Xcode project’s “General” settings. Drag RealmSwift.framework and Realm.framework from the appropriate Swift-versioned directory for your project in ios/, osx/, tvos/ or watchos/ directory to the “Embedded Binaries” section. Make sure Copy items if needed is selected (except if using Realm on multiple platforms in your project) and click Finish.

Importing the Realm Framework

At the top of your Swift source files, use import RealmSwift to import Realm Swift and make it available for use with your code. That’s all you need to get started!

tvOS

Because writing to the Documents directory is prohibited on tvOS, the default Realm location is set to NSCachesDirectory. However, please be mindful that tvOS can purge files in the Caches directory at any point, so we encourage you to rely on Realm as a rebuildable cache rather than storing important user data.

If you would like to share a Realm file between a tvOS app and a TV services extension (e.g. Top Shelf extension), you have to use the Library/Caches/ directory within the shared container for the application group.

Xcode Plugin

Our Xcode plugin makes it easy to generate new Realm models.

The easiest way to install the Realm Xcode plugin is through Alcatraz under the name “RealmPlugin”. You can also install the plugin manually by opening plugin/RealmPlugin.xcodeproj contained in the release zip and clicking build. You will need to quit and relaunch Xcode to see our plugin. If you use the Xcode menu to create a new file (File > New > File… — or ⌘N) you should see a new option to create a new Realm model.

API Reference

Examples

You can find example applications for both iOS and OS X in our release zip under examples/, demonstrating how to use many features of Realm like migrations, how to use it with UITableViewControllers, encryption, command-line tools and much more.

If you’re using a crash reporter (like Crashlytics or HockeyApp), make sure to enable log collection. Realm logs metadata information (but no user data) when throwing exceptions and in irrecoverable situations, and these messages can help debug when things go wrong.

Models

Realm data models are defined using regular Swift classes with properties. Simply subclass Object or an existing model class to create your Realm data model objects. Realm model objects mostly function like any other Swift objects - you can add your own methods and protocols to them and use them like you would any other object. The main restriction is that you can only use an object on the thread which it was created.

If you have installed our Xcode Plugin there will be a nice template to create the Swift file in the “New File…” dialog.

Relationships and nested data structures are modeled simply by including properties of the target type or Lists for typed lists of objects.

Since Realm parses all models defined in your code at launch, they must all be valid, even if they are never used.

When using Realm from Swift, the Swift.reflect(_:) function is used to determine information about your models, which requires that calling init() succeed. This means that all non-optional properties must have a default value.

Supported Types

CGFloat properties are discouraged, as the type is not platform independent.

String, NSDate and NSData properties can be optional. Object properties must be optional. Storing optional numbers is done using RealmOptional.

Relationships

Objects can be linked to each other by using Object and List properties. Lists have an interface very similar to Array and objects contained in a List can be accessed using indexed subscripting. Unlike Arrays, Lists only hold Objects of a single subclass type. For more details see List.

To-One Relationships

For many-to-one or one-to-one relationships, simply declare a property with the type of your Object subclass:

classDog:Object{// ... other property declarationsdynamicvarowner:Person?// to-one relationships must be optional}

You can use this property like you would any other:

letjim=Person()letrex=Dog()rex.owner=jim

When using Object properties, you can access nested properties using normal property syntax. For example rex.owner?.address.country will traverse the object graph and automatically fetch each object from Realm as needed.

To-Many Relationships

You can define a to-many relationship using List properties. Lists contain other Objects of a single type and have an interface very similar to a mutable Array.

A List may contain multiple references to the same Realm object, including objects with primary keys. For example, you may create an empty List and insert the same object into it three times; the List will then return that object if the element at any of the indices 0, 1, and 2 is accessed.

To add a “dogs” property on our Person model that links to multiple dogs, we can declare a property of type List<Dog>:

Inverse Relationships

Links are unidirectional. So if a to-many property Person.dogs links to a Dog instance and a to-one property Dog.owner links to Person, these links are independent from one another. Appending a Dog to a Person instance’s dogs property doesn’t automatically set the dog’s owner property to this Person. Because manually synchronizing pairs of relationships is error prone, complex and duplicates information, Realm provides linking objects properties to represent these inverse relationships.

With linking objects properties, you can obtain all objects that link to a given object from a specific property. For example, a Dog object can have a property named owners that contains all of the Person objects that have this exact Dog object in their dogs property. This is done by making the owners property of type LinkingObjects and then specifying the relationship that it has with the Person object.

Optional Properties

String, NSDate, and NSData properties can be declared as optional or non-optional using the standard Swift syntax. Optional numeric types are declared using RealmOptional:

classPerson:Object{// Optional string property, defaulting to nildynamicvarname:String?=nil// Optional int property, defaulting to nil// RealmOptional properties should always be declared with `let`,// as assigning to them directly will not work as desiredletage=RealmOptional<Int>()}letrealm=try!Realm()try!realm.write(){varperson=realm.create(Person.self,value:["Jane",27])// Reading from or modifying a `RealmOptional` is done via the `value` propertyperson.age.value=28}

Property Attributes

Realm model properties need the dynamic var attribute in order for these properties to become accessors for the underlying database data.

There are three exceptions to this: LinkingObjects, List and RealmOptional properties cannot be declared as dynamic because generic properties cannot be represented in the Objective‑C runtime, which is used for dynamic dispatch of dynamic properties, and should always be declared with let.

Indexing a property will greatly speed up queries where the property is compared for equality (i.e. the = and IN operators), at the cost of slower insertions.

Auto-Updating Objects

Object instances are live, auto-updating views into the underlying data, which means objects never have to be refreshed. Modifying the properties of an object will immediately reflect in any other instances referring to the same object.

This aspect of Object not only keeps Realm fast and efficient, it allows your code to be simpler and more reactive. For example, if your UI code is dependent on a specific Realm object, you don’t need to worry about refreshing or re-fetching it before triggering a UI redraw.

You can subscribe to Realm notifications to know when Realm data in an object is updated, indicating when your app’s UI should be refreshed. Alternatively, you can use key-value observation to be notified when a specific property of an Object is updated.

Primary Keys

Override Object.primaryKey() to set the model’s primary key. Declaring a primary key allows objects to be looked up and updated efficiently and enforces uniqueness for each value. Once an object with a primary key is added to a Realm, the primary key cannot be changed.

Ignored Properties

Override Object.ignoredProperties() to prevent Realm from persisting model properties. Realm won’t interfere with the regular operation of these properties: they’ll be backed by ivars and you can freely override their setters and getters.

Ignored properties behave exactly the same way as normal properties on normal Objective-C or Swift classes. They do not support any Realm-specific functionality. For example, they can’t be used in queries, they won’t automatically update their value if the same property on another instance representing the same Realm object is changed, and they won’t trigger notifications when changed. They can still be observed using KVO, however.

Model Inheritance

Realm allows models to be further subclassed, allowing for much code reuse across models, but some Cocoa features that contribute to the runtime’s rich class polymorphism aren’t available. Here’s what’s possible:

Class methods, instance methods and properties on parent classes are inherited in their child classes.

Methods and functions that take parent classes as arguments can operate on subclasses.

RealmCollection, a protocol defining the common interface to which all Realm Collections conform.

AnyRealmCollection, a type-erased class that can forward calls to a concrete Realm Collection like a Results, List or LinkingObjects.

Realm Collections conform to the RealmCollection protocol, which ensures they behave consistently. This protocol inherits from CollectionType so that it may be used in the same ways as other standard library collections. Additional common Realm Collection APIs are declared in this protocol, such as querying, sorting and aggregate operations, among others. Lists have additional mutation operations that extend beyond the protocol interface such as adding and deleting objects.

Using the RealmCollection protocol, you can write generic code that can operate on any Realm collection:

funcoperateOn<C:RealmCollection>(collection:C){// Collection could be either Results or Listprint("operating on collection containing \(collection.count) objects")}

Because protocols with associated types in Swift aren’t concrete, it’s necessary to use a type-erased wrapper such as AnyRealmCollection in order to store this collection as a property or variable:

Writes

All changes to an object (addition, modification and deletion) must be done within a write transaction.

Realm objects can be instantiated and used as unmanaged objects (i.e. not yet added to a Realm) just like regular Swift objects. To share objects between threads or re-use them between app launches, however, you must add them to a Realm. Adding an object to a Realm must be done within a write transaction. Since write transactions incur non-negligible overhead, you should architect your code to minimize the number of write transactions.

Realm write operations are synchronous and blocking, not asynchronous. If thread A starts a write operation, then thread B starts a write operation on the same Realm before thread A is finished, thread A must finish and commit its transaction before thread B’s write operation takes place. Write operations always refresh automatically on beginWrite(), so no race condition is created by overlapping writes.

Because write transactions could potentially fail like any other disk IO operations, both Realm.write() & Realm.commitWrite() are marked as throws so you can handle and recover from failures like running out of disk space. There are no other recoverable errors. For brevity, our code samples don’t handle these errors, but you certainly should in your production applications.

Creating Objects

When you have defined a model you can instantiate your Object subclass and add the new instance to the Realm. Consider this simple model:

classDog:Object{dynamicvarname=""dynamicvarage=0}

We can create new objects in several ways:

// (1) Create a Dog object and then set its propertiesvarmyDog=Dog()myDog.name="Rex"myDog.age=10// (2) Create a Dog object from a dictionaryletmyOtherDog=Dog(value:["name":"Pluto","age":3])// (3) Create a Dog object from an arrayletmyThirdDog=Dog(value:["Fido",5])

The most obvious is to use the designated initializer to create an object.

Objects can also be created from dictionaries using appropriate keys and values.

Finally, Object subclasses can be instantiated using arrays. The values in the array have to be in the same order as the corresponding properties in the model.

Nested Objects

If an object has properties that are Objects or Lists, these can be set recursively using nested arrays and/or dictionaries. You simply replace each object with a dictionary or array representing its properties:

// Instead of using already existing dogs...letaPerson=Person(value:["Jane",30,[aDog,anotherDog]])// ...we can create them inlineletanotherPerson=Person(value:["Jane",30,[["Buster",5],["Buddy",6]]])

This will work for any combination of nested arrays and dictionaries. Note that a List may only contain Objects, not basic types such as String.

Adding Objects

You can add an object to a Realm like so:

// Create a Person objectletauthor=Person()author.name="David Foster Wallace"// Get the default Realmletrealm=try!Realm()// You only need to do this once (per thread)// Add to the Realm inside a transactiontry!realm.write{realm.add(author)}

After you have added the object to the Realm you can continue using it, and all changes you make to it will be persisted (and must be made within a write transaction). Any changes are made available to other threads that use the same Realm when the write transaction is committed.

Please note that writes block each other, and will block the thread they are made on if multiple writes are in progress. This is similar to other persistence solutions and we recommend that you use the usual best practice for this situation: offloading your writes to a separate thread.

Thanks to Realm’s MVCC architecture, reads are not blocked while a write transaction is open. Unless you need to make simultaneous writes from many threads at once, you should favor larger write transactions that do more work over many fine-grained write transactions. When you commit a write transaction to a Realm, all other instances of that Realm will be notified, and be updated automatically.

Updating Objects

Realm provides a few ways to update objects, all of which offer different tradeoffs depending on the situation. Choose which one is best for your situation:

Typed Updates

You can update any object by setting its properties within a write transaction.

// Update an object with a transactiontry!realm.write{author.name="Thomas Pynchon"}

Creating and Updating Objects With Primary Keys

If your model class includes a primary key, you can have Realm intelligently update or add objects based off of their primary key values using Realm().add(_:update:).

// Creating a book with the same primary key as a previously saved bookletcheeseBook=Book()cheeseBook.title="Cheese recipes"cheeseBook.price=9000cheeseBook.id=1// Updating book with id = 1try!realm.write{realm.add(cheeseBook,update:true)}

If a Book object with a primary key value of ‘1’ already existed in the database, then that object would simply be updated. If it did not exist, then a completely new Book object would be created and added to the database.

You can also partially update objects with primary keys by passing just a subset of the values you wish to update, along with the primary key:

// Assuming a "Book" with a primary key of `1` already exists.try!realm.write{realm.create(Book.self,value:["id":1,"price":9000.0],update:true)// the book's `title` property will remain unchanged.}

You may not pass update: true for object types which don’t define a primary key.

Please note that when updating objects, nil is still considered a valid value for optional properties. If you supply a dictionary with nil property values, then these will be applied to your object and those properties will be emptied. To ensure you don’t experience any unplanned data loss, please make sure to provide only the properties you wish to update when using this method.

Key-Value Coding

Object, Result, and List all conform to key-value coding (KVC). This can be useful when you need to determine which property to update at runtime.

Applying KVC to a collection is a great way to update objects in bulk without the overhead of iterating over a collection while creating accessors for every item.

letpersons=realm.objects(Person.self)try!realm.write{persons.first?.setValue(true,forKeyPath:"isFirst")// set each person's planet property to "Earth"persons.setValue("Earth",forKeyPath:"planet")}

Deleting Objects

Pass the object to be deleted to the Realm().delete(_:) method within a write transaction.

// let cheeseBook = ... Book stored in Realm// Delete an object with a transactiontry!realm.write{realm.delete(cheeseBook)}

You can also delete all objects stored in a Realm. Note the Realm file will maintain its size on disk to efficiently reuse that space for future objects.

// Delete all objects from the realmtry!realm.write{realm.deleteAll()}

Queries

Queries return a Results instance, which contains a collection of Objects. Results have an interface very similar to Array and objects contained in a Results can be accessed using indexed subscripting. Unlike Arrays, Results only hold Objects of a single subclass type.

All queries (including queries and property access) are lazy in Realm. Data is only read when the properties are accessed.

Results to a query are not copies of your data: modifying the results of a query (within a write transaction) will modify the data on disk directly. Similarly, you can traverse your graph of relationships directly from the Objects contained in a Results.

Execution of a query is deferred until the results are used. This means that chaining several temporary Results to sort and filter your data does not perform extra work processing the intermediate state.

Once the query has been executed, or a notification block has been added, the Results is kept up to date with changes made in the Realm, with the query execution performed on a background thread when possible.

The most basic method for retrieving objects from a Realm is Realm().objects(_:), which returns a Results of all Object instances of the subclass type being queried from the default Realm.

letdogs=realm.objects(Dog.self)// retrieves all Dogs from the default Realm

Filtering

If you’re familiar with NSPredicate, then you already know how to query in Realm. Objects, Realm, List, and Results all provide methods that allow you to query for specific Object instances by simply passing in an NSPredicate instance, predicate string, or predicate format string just as you would when querying an NSArray.

For example, the following would extend our earlier example by calling Results().filter(_:...) to retrieve all tan-colored dogs whose names begin with ‘B’ from the default Realm:

// Query using a predicate stringvartanDogs=realm.objects(Dog.self).filter("color = 'tan' AND name BEGINSWITH 'B'")// Query using an NSPredicateletpredicate=NSPredicate(format:"color = %@ AND name BEGINSWITH %@","tan","B")tanDogs=realm.objects(Dog.self).filter(predicate)

The comparison operators == and != are supported for boolean properties.

For String and NSData properties, we support the ==, !=, BEGINSWITH, CONTAINS, and ENDSWITH operators, such as name CONTAINS ‘Ja’

For String properties, the LIKE operator may be used to compare the left hand property with the right hand expression: ? and * are allowed as wildcard characters, where ? matches 1 character and * matches 0 or more characters. Such as value LIKE '?bc*' matching strings like “abcde” and “cbc”.

Case-insensitive comparisons for strings, such as name CONTAINS[c] ‘Ja’. Note that only characters “A-Z” and “a-z” will be ignored for case. Can be combined with the [d] modifier.

Diacritic-insensitive comparisons for strings, such as name BEGINSWITH[d] ‘e’ matching étoile. Can be combined with the [c] modifier.

Realm supports the following compound operators: “AND”, “OR”, and “NOT”. Such as name BEGINSWITH ‘J’ AND age >= 32

The containment operand IN such as name IN {‘Lisa’, ‘Spike’, ‘Hachi’}

Nil comparisons ==, !=, e.g. Results<Company>().filter("ceo == nil"). Note that Realm treats nil as a special value rather than the absence of a value, so unlike with SQL nil equals itself.

ANY comparisons, such as ANY student.age < 21

The aggregate expressions @count, @min, @max, @sum and @avg are supported on List and Results properties, e.g. realm.objects(Company.self).filter("[email protected] > 5") to find all companies with more than five employees.

Subqueries are supported with the following limitations:

@count is the only operator that may be applied to the SUBQUERY expression.

Sorting

Results allows you to specify a sort criteria and order based on a key path, a property, or on one or more sort descriptors. For example, the following calls sorts the dogs returned from the example above alphabetically by name:

Note that sorted(byKeyPath:) and sorted(byProperty:) do not support multiple properties as sort criteria, and cannot be chained (only the last call to sorted will be used). To sort by multiple properties, use the sorted(by:) method with multiple SortDescriptor objects.

Note that the order of Results is only guaranteed to stay consistent when the query is sorted. For performance reasons, insertion order is not guaranteed to be preserved. If you need to maintain order of insertion, some solutions are proposed here.

Chaining

One unique property of Realm’s query engine is the ability to chain queries with very little transactional overhead when compared to traditional databases that require a separate trip to the database server for each successive query.

For example, if we wanted a result set for just tan colored dogs, and tan colored dogs whose names also start with ‘B’, you might chain two queries like this:

Auto-Updating Results

Results instances are live, auto-updating views into the underlying data, which means results never have to be re-fetched. They always reflect the current state of the Realm on the current thread, including during write transactions on the current thread. The one exception to this is when using for...in enumeration, which will always enumerate over the objects which matched the query when the enumeration is begun, even if some of them are deleted or modified to be excluded by the filter during the enumeration.

This property of Results not only keeps Realm fast and efficient, it allows your code to be simpler and more reactive. For example, if your view controller relies on the results of a query, you can store the Results in a property and access it without having to make sure to refresh its data prior to each access.

You can subscribe to Realm notifications to know when Realm data is updated, indicating when your app’s UI should be refreshed for example, without having to re-fetch your Results.

Since results are auto-updating, it’s important to not rely on indices and counts staying constant. The only time a Results is frozen is when fast-enumerating over it, which makes it possible to mutate the objects matching a query while enumerating over it:

Limiting Results

Most other database technologies provide the ability to ‘paginate’ results from queries (such as the ‘LIMIT’ keyword in SQLite). This is often done out of necessity to avoid reading too much from disk, or pulling too many results into memory at once.

Since queries in Realm are lazy, performing this sort of paginating behavior isn’t necessary at all, as Realm will only load objects from the results of the query once they are explicitly accessed.

If for UI-related or other implementation reasons you require a specific subset of objects from a query, it’s as simple as taking the Results object, and reading out only the objects you need.

// Loop through the first 5 Dog objects// restricting the number of objects read from diskletdogs=try!Realm().objects(Dog.self)foriin0..<5{letdog=dogs[i]// ...}

Realms

The Default Realm

You may have noticed so far that we have initialized access to our realm variable by calling Realm(). That method returns a Realm object that maps to a file called “default.realm” under the Documents folder (iOS) or Application Support folder (OS X) of your app.

Realm Configuration

Configuring things like where your Realm files are stored is done through Realm.Configuration. The configuration can either be passed to Realm(configuration: config) each time you need a Realm instance, or you can set the configuration to use for the default Realm with Realm.Configuration.defaultConfiguration = config.

For example, suppose you have an application where users have to log in to your web backend, and you want to support quickly switching between accounts. You could give each account its own Realm file that will be used as the default Realm by doing the following:

funcsetDefaultRealmForUser(username:String){varconfig=Realm.Configuration()// Use the default directory, but replace the filename with the usernameconfig.fileURL=config.fileURL!.deletingLastPathComponent().appendingPathComponent("\(username).realm")// Set this as the configuration used for the default RealmRealm.Configuration.defaultConfiguration=config}

Other Realms

It’s sometimes useful to have multiple Realms persisted at different locations. For example, you may want to bundle some data with your application in a Realm file, in addition to your main Realm. You can do this with the following code:

letconfig=Realm.Configuration(// Get the URL to the bundled filefileURL:Bundle.main.url(forResource:"MyBundledData",withExtension:"realm"),// Open the file in read-only mode as application bundles are not writeablereadOnly:true)// Open the Realm with the configurationletrealm=try!Realm(configuration:config)// Read some data from the bundled Realmletresults=realm.objects(Dog.self).filter("age > 5")

Please note that if a custom URL is used to initialize a Realm, it must be in a location with write permissions. The most common location to store writable Realm files is the “Documents” directory on iOS and the “Application Support” directory on OS X. Please respect Apple’s iOS Data Storage Guidelines, which recommend that documents that can be regenerated be stored in the <Application_Home>/Library/Caches directory.

In-Memory Realms

Normally Realms are persisted to disk, but you can also create ones which operate purely in memory by setting the inMemoryIdentifier rather than the fileURL on your Realm.Configuration.

In-memory Realms do not save data across app launches, but all other features of Realm will work as expected, including querying, relationships and thread-safety. This is a useful option if you need flexible data access without the overhead of disk persistence.

In-memory Realms create several files in a temporary directory for coordinating things like cross-process notifications. No data is actually written to the files unless the operating system needs to swap to disk due to memory pressure.

Notice: When all in-memory Realm instances with a particular identifier go out of scope with no references, all data in that Realm is deleted. We recommend holding onto a strong reference to any in-memory Realms during your app’s lifetime. (This is not necessary for on-disk Realms.)

Error Handling

Like any disk IO operation, creating a Realm instance could sometimes fail if resources are constrained. In practice, this can only happen the first time a Realm instance is created on a given thread. Subsequent accesses to a Realm from the same thread will reuse a cached instance and will always succeed.

To handle errors when first accessing a Realm on a given thread, use Swift’s built-in error handling mechanism:

do{letrealm=tryRealm()}catchleterrorasNSError{// handle error}

Asynchronously Opening Realms

If opening a Realm might require a time-consuming operation, such as applying migrations, compaction or downloading the remote contents of a synchronized Realm, you should use the asyncOpen API to perform all work needed to get the Realm to a usable state on a background thread before dispatching to the given queue. You should also use asyncOpen with Realms that are set read-only.

In addition, synchronized Realms wait for all remote content available at the time the operation began to be downloaded and available locally. For example:

letconfig=Realm.Configuration(syncConfiguration:SyncConfiguration(user:user,realmURL:realmURL))Realm.asyncOpen(configuration:config){realm,errorinifletrealm=realm{// Realm successfully opened, with all remote data available}elseifleterror=error{// Handle error that occurred while opening or downloading the contents of the Realm}}

Copying Objects Between Realms

Copying Realm objects to other Realms is as simple as passing in the original object to Realm().create(_:value:update:). For example, realm.create(MyObjectSubclass.self, value: originalObjectInstance). Remember that Realm objects can only be accessed from the thread on which they were first created, so this copy will only work for Realms on the same thread.

Note that Realm().create(_:value:update:) does not support handling cyclical object graphs. Do not pass in an object containing relationships involving objects that refer back to their parents, either directly or indirectly.

Finding a Realm File

If you need help finding your app’s Realm file, check this StackOverflow answer for detailed instructions.

Auxiliary Realm Files

Alongside the standard .realm files, Realm also generates and maintains additional files and directories for its own internal operations.

.realm.lock - A lock file for resource locks.

.realm.management - Directory of interprocess lock files.

.realm.note - A named pipe for notifications.

These files don’t have any effect on .realm database files, and won’t cause any erroneous behavior if their parent database file is deleted or replaced.

When reporting Realm issues, please be sure to include these auxiliary files along with your main .realm file as they contain useful information for debugging purposes.

Bundling a Realm with an App

It’s common to seed an app with initial data, making it available to your users immediately on first launch. Here’s how to do this:

First, populate the Realm. You should use the same data model as your final, shipping app to create a Realm and populate it with the data you wish to bundle with your app. Since Realm files are cross-platform, you can use an OS X app (see our JSONImport example) or your iOS app running in the simulator.

In the code where you’re generating this Realm file, you should finish by making a compacted copy of the file (see Realm().writeCopyToPath(_:encryptionKey:)). This will reduce the Realm’s file size, making your final app lighter to download for your users.

Drag the new compacted copy of your Realm file to your final app’s Xcode Project Navigator.

If the bundled Realm contains fixed data that you don’t need to modify, you can open it directly from the bundle path by setting readOnly = true on the Realm.Configuration object. Otherwise, if it’s initial data that you’ll be modifying, you can copy the bundled file to your application’s Documents directory using NSFileManager.default.copyItemAtPath(_:toPath:).

Class Subsets

In some scenarios you may wish to limit which classes can be stored in a specific Realm. For example, if you have two teams working on different components of your application which both use Realm internally, you may not want to have to coordinate migrations between them. You can do this by setting the objectTypes property of your Realm.Configuration:

Compacting Realms

Realm’s architecture means that file sizes are always larger than the latest state of the data it contains. See our docs on Threading for some of the reasons why this architecture enables some of Realm’s great performance, concurrency and safety advantages.

Additionally, to avoid making expensive system calls to expand the size of a file very frequently, Realm files generally aren’t shrunk at runtime, instead growing by distinct size increments, and new data being written within the free space tracked inside the file.

However, there are cases in which a significant portion of a Realm file is comprised of free space. So this release adds a shouldCompactOnLaunch block property to a Realm’s configuration object to determine if the Realm should be compacted before being returned. For example:

letconfig=Realm.Configuration(shouldCompactOnLaunch:{totalBytes,usedBytesin// totalBytes refers to the size of the file on disk in bytes (data + free space)// usedBytes refers to the number of bytes used by data in the file// Compact if the file is over 100MB in size and less than 50% 'used'letoneHundredMB=100*1024*1024return(totalBytes>oneHundredMB)&&(Double(usedBytes)/Double(totalBytes))<0.5})do{// Realm is compacted on the first open if the configuration block conditions were met.letrealm=tryRealm(configuration:config)}catch{// handle error compacting or opening Realm}

Under the hood, the compaction operation reads the entire contents of the Realm file, rewrites it to a new file at a different location, then replaces the original file. Depending on the amount of data in a file, this may be an expensive operation.

We encourage you to experiment with the numbers to identify a good balance between performing the compaction too often and letting Realm files grow too large.

Finally, if another process is accessing the Realm, compaction will be skipped even if the configuration block’s conditions were met. That’s because compaction cannot be safely performed while a Realm is being accessed.

Setting a shouldCompactOnLaunch block is not supported for synchronized Realms. This is because compaction doesn’t preserve transaction logs, which must be kept for synchronization.

Deleting Realm Files

In some cases, such as clearing caches, or resetting your entire dataset, it may be appropriate to completely delete a Realm file from disk.

Because Realm avoids copying data into memory except when absolutely required, all objects managed by a Realm contain references to the file on disk, and must be deallocated before the file can be safely deleted. This includes all objects read from (or added to) the Realm, all List, Results, and ThreadSafeReference objects, and the Realm itself.

In practice, this means that deleting a Realm file should be done either on application startup before you have opened the Realm, or after only opening the Realm within an explicit autorelease pool, which ensures that all of the Realm objects will have been deallocated.

Finally, although not strictly necessary, you should delete auxiliary Realm files as well as the main Realm file to fully clean up all related files.

Using Realm with Background App Refresh

On iOS 8 and above, files inside apps are automatically encrypted using NSFileProtection whenever the device is locked. If your app attempts to do any work involving Realm while the device is locked and the NSFileProtection attributes of your Realm files are set to encrypt them (which is the case by default), an open() failed: Operation not permitted exception will be thrown.

In order to handle this, it is necessary to ensure that the file protection attributes applied to both the Realm file itself and its auxiliary files is downgraded to a less strict one that allows file access even when the device is locked, such as NSFileProtectionCompleteUntilFirstUserAuthentication.

If you choose to opt out of complete iOS file encryption in this way, we encourage you to use Realm’s own built-in encryption to ensure your data is still properly secured.

Since the auxiliary files can sometimes be lazily created and deleted mid-operation, we recommend that you apply the file protection attributes to the parent folder containing these Realm files. This will ensure the attribute is properly applied to all of the relevant Realm files, regardless of their creation time.

Threading

Realm read transaction lifetimes are tied to the memory lifetime of Realm instances. Avoid “pinning” old Realm transactions by using auto-refreshing Realms and wrapping all use of Realm APIs from background threads in explicit autorelease pools.

Within individual threads you can just treat everything as regular objects without worrying about concurrency or multithreading. There is no need for any locks or resource coordination to access them (even if they are simultaneously being modified on other threads) and it is only modifying operations that have to be wrapped in write transactions.

Realm makes concurrent usage easy by ensuring that each thread always has a consistent view of the Realm. You can have any number of threads working on the same Realms in parallel, and since they all have their own snapshots, they will never cause each other to see inconsistent state.

The only thing you have to be aware of is that you cannot have multiple threads sharing the same instances of Realm objects. If multiple threads need to access the same objects they will each need to get their own instances (otherwise changes happening on one thread could cause other threads to see incomplete or inconsistent data).

Seeing Changes From Other Threads

On the main UI thread (or any thread with a runloop) objects will automatically update with changes from other threads between each iteration of the runloop. At any other time you will be working on the snapshot, so individual methods always see a consistent view and never have to worry about what happens on other threads.

When you initially open a Realm on a thread, its state will be based off the most recent successful write commit, and it will remain on that version until refreshed. Realms are automatically refreshed at the start of every runloop iteration, unless Realm’s autorefresh property is set to NO. If a thread has no runloop (which is generally the case in a background thread), then Realm.refresh() must be called manually in order to advance the transaction to the most recent state.

Realms are also refreshed when write transactions are committed (Realm.commitWrite()).

Failing to refresh Realms on a regular basis could lead to some transaction versions becoming “pinned”, preventing Realm from reusing the disk space used by that version, leading to larger file sizes. Refer to our Current Limitations for more details on this effect.

Passing Instances Across Threads

Unmanaged instances of Objects behave exactly as regular NSObject subclasses, and are safe to pass across threads.

Instances of Realm, Results, or List, or managed instances of Object are thread-confined, meaning that they can only be used on the thread on which they were created, otherwise an exception is thrown*. This is one way Realm enforces transaction version isolation. Otherwise, it would be impossible to determine what should be done when an object is passed between threads at different transaction versions without a potentially extensive relationship graph.

Realm exposes a mechanism to safely pass thread-confined instances in three steps:

Initialize a ThreadSafeReference with the thread-confined object.

Pass that ThreadSafeReference to a destination thread or queue.

Resolve this reference on the target Realm by calling Realm.resolve(_:). Use the returned object as you normally would.

A ThreadSafeReference object must be resolved at most once. Failing to resolve a ThreadSafeReference will result in the source version of the Realm being pinned until the reference is deallocated. For this reason, ThreadSafeReference should be short-lived.

* Some properties and methods on these types can be accessed from any thread:

Using a Realm Across Threads

To access the same Realm file from different threads, you must initialize a new Realm to get a different instance for every thread of your app. As long as you specify the same configuration, all Realm instances will map to the same file on disk.

Sharing Realm instances across threads is not supported. Realm instances accessing the same Realm file must also all use the same Realm.Configuration.

Realm can be very efficient when writing large amounts of data by batching together multiple mutations within a single transaction. Transactions can also be performed in the background using Grand Central Dispatch to avoid blocking the main thread. Realm objects are not thread safe and cannot be shared across threads, so you must get a Realm instance in each thread/dispatch queue in which you want to read or write. Here’s an example of inserting a million objects in a background queue:

DispatchQueue(label:"background").async{autoreleasepool{// Get realm and table instances for this threadletrealm=try!Realm()// Break up the writing blocks into smaller portions// by starting a new transactionforidx1in0..<1000{realm.beginWrite()// Add row via dictionary. Property order is ignored.foridx2in0..<1000{realm.create(Person.self,value:["name":"\(idx1)","birthdate":Date(timeIntervalSince1970:TimeInterval(idx2))])}// Commit the write transaction// to make this data available to other threadstry!realm.commitWrite()}}}

JSON

Realm does not have direct support for JSON, but it’s possible to add Objects from JSON using the output of NSJSONSerialization.JSONObjectWithData(_:options:). The resulting KVC-compliant object can be used to add/update Objects using the standard APIs for creating and updating objects.

// A Realm Object that represents a cityclassCity:Object{dynamicvarcity=""dynamicvarid=0// other properties left out ...}letdata="{\"name\": \"San Francisco\", \"cityId\": 123}".data(using:.utf8)!letrealm=try!Realm()// Insert from NSData containing JSONtry!realm.write{letjson=try!JSONSerialization.jsonObject(with:data,options:[])realm.create(City.self,value:json,update:true)}

If there are nested objects or arrays in the JSON, these will be mapped automatically to to-one and to-many relationships - see the Nested Objects section for more detail.

When inserting or updating JSON data in a Realm using this approach, be aware that Realm expects the JSON property names and types to exactly match the Object properties. For example:

float properties should be initialized with float-backed NSNumbers.

NSDate and NSData properties cannot be automatically inferred from strings, but should be converted to the appropriate type before passing to Realm().create(_:value:update:).

If a JSON null (i.e. NSNull) is supplied for a required property, an exception will be thrown.

If no property is supplied on insert for a required property, an exception will be thrown.

Realm will ignore any properties in the JSON not defined by the Object.

If your JSON schema doesn’t align exactly with your Realm objects, we recommend you use a third party model mapping framework in order to transform your JSON. Swift has a thriving set of actively maintained model mapping frameworks which work with Realm, some of which are listed in the realm-cocoa repository.

Notifications

It is possible to register to be notified whenever a Realm, Results, List or LinkingObjects is updated by calling the addNotificationBlock method.

Notifications are delivered as long as a reference is held to the returned notification token. You should keep a strong reference to this token on the class registering for updates, as notifications are automatically unregistered when the notification token is deallocated.

How Notifications are Delivered

Notifications are always delivered on the thread that they were originally registered on. That thread must have a currently running run loop. If you wish to register notifications on a thread other than the main thread, you are responsible for configuring and starting a run loop on that thread if one doesn’t already exist.

Notification handlers are asynchronously called after each relevant write transaction is committed, no matter which thread or process the write transaction took place on.

If a Realm is advanced to the latest version as part of starting a write transaction, notification handlers might be called synchronously. This will happen if, when the Realm was advanced to the latest version, Realm entities being observed were modified or deleted in a way that would trigger notifications. Such notifications will run within the context of the current write transaction, meaning attempting to begin a write transaction within the notification handler will cause Realm to throw an exception. If your app is architected in such a way that this scenario could occur, you can use Realm.isInWriteTransaction to determine whether you are already inside a write transaction or not.

Since notifications are delivered using a run loop, the delivery of notifications might be delayed by other activity on the run loop. When notifications can’t be delivered immediately, changes from multiple write transactions may be coalesced into a single notification.

Realm Notifications

A notification handler can be registered on an entire Realm. Every time a write transaction involving that Realm is committed, no matter which thread or process the write transaction took place on, the notification handler will be fired:

Collection Notifications

Collection notifications are different from Realm notifications in that they contain information that describes what changes have occurred at a fine-grained level. This consists of the indices of objects that have been inserted, deleted, or modified since the last notification.

Collection notifications are delivered asynchronously, first with the initial results, and then again after each write transaction which changes either any of the objects in the collection, or which objects are in the collection.

These changes can be accessed via the RealmCollectionChange parameter that is passed to the notification block. This object holds information about the indices affected by deletions, insertions and modifications.

The former two, deletions and insertions, record the indices whenever objects start and stop being part of the collection. This takes into account when you add objects to the Realm or delete them from the Realm. For Results this also applies when you filter for specific values and the object was changed so that it is now matching the query or not matching anymore. For collections based either on List or LinkingObjects, including derived Results, this applies in addition when objects are added or removed from the relationship.

You’re notified about modifications whenever a property of an object has changed, which was previously part of the collection and is still part of it. This happens as well when to-one and to-many relationships change, but doesn’t take changes on inverse relationships into account.

So let’s assume you’re observing a list of dog owners as given by the model code above. You will be notified about modifications for a matched Person object when:

You modify the Person’s name property.

You add or remove a Dog to the Person’s dogs property.

You modify the age property of a Dog belonging to that Person.

This makes it possible to discretely control the animations and visual updates made to the content inside your UI, instead of arbitrarily reloading everything each time a notification occurs.

classViewController:UITableViewController{varnotificationToken:NotificationToken?=niloverridefuncviewDidLoad(){super.viewDidLoad()letrealm=try!Realm()letresults=realm.objects(Person.self).filter("age > 5")// Observe Results NotificationsnotificationToken=results.addNotificationBlock{[weakself](changes:RealmCollectionChange)inguardlettableView=self?.tableViewelse{return}switchchanges{case.initial:// Results are now populated and can be accessed without blocking the UItableView.reloadData()breakcase.update(_,letdeletions,letinsertions,letmodifications):// Query results have changed, so apply them to the UITableViewtableView.beginUpdates()tableView.insertRows(at:insertions.map({IndexPath(row:$0,section:0)}),with:.automatic)tableView.deleteRows(at:deletions.map({IndexPath(row:$0,section:0)}),with:.automatic)tableView.reloadRows(at:modifications.map({IndexPath(row:$0,section:0)}),with:.automatic)tableView.endUpdates()breakcase.error(leterror):// An error occurred while opening the Realm file on the background worker threadfatalError("\(error)")break}}}deinit{notificationToken?.stop()}}

Object Notifications

Realm supports object-level notifications. You may register a notification on a particular Realm object in order to be notified if the object is deleted, or whenever any of the managed properties on the object have their values modified. (This also applies to managed properties that have their values set to their existing value.)

Only objects managed by a Realm may have notification handlers registered on them.

For write transactions performed on different threads or in different processes, the block will be called when the Realm that manages the object is (auto)refreshed to a version including the changes, while for local write transactions it will be called at some point in the future after the write transaction is committed.

The notification handler takes an ObjectChange enum value which indicates if the object was deleted, if property values on the object were changed, or if an error occurred.

The notification block will be called with ObjectChange.deleted if the object was deleted. The block will never be called again.

The block will be called with ObjectChange.change if the object’s properties were changed. The enum will contain an array of PropertyChange values. Each of these values contains the name of a property that was changed (as a string), the previous value, and the current value.

The block will be called with ObjectChange.error containing an NSError if an error occurs. The block will never be called again.

Interface-Driven Writes

Notifications in Realm are always delivered asynchronously so they never block the main UI thread, causing your app to stutter. However, there are situations when changes need to be done synchronously, on the main thread, and reflected in the UI instantly. We refer to these transactions as interface-driven writes.

For example, say a user adds an item to a table view. The UI should ideally animate this operation and start this process as soon as the user initiates the action.

However, when the Realm change notification for this insertion is delivered a little later, it will indicate that an object was added to the collection backing the table view and we will once again attempt to insert a new row in the UI. This double insertion leads to inconsistent state between the UI and the backing data, which in turn will crash your app! 💥NSInternalInconsistencyException💥

When performing an interface-driven write, pass the notification tokens of the notification blocks that shouldn’t react to a change for a second time to Realm.commitWrite(withoutNotifying:).

This feature is especially useful when using fine-grained collection notifications with a synchronized Realm, because many of the workarounds to previously account for interface-driven writes rely on controlling the full state of when the app can perform changes. With synchronized Realms, changes are applied whenever they’re synchronized, which can happen at any point in the app’s lifetime.

// Add fine-grained notification blocktoken=collection.addNotificationBlock{changesinswitchchanges{case.initial:tableView.reloadData()breakcase.update(_,letdeletions,letinsertions,letmodifications):// Query results have changed, so apply them to the UITableViewtableView.beginUpdates()tableView.insertRows(at:insertions.map({IndexPath(row:$0,section:0)}),with:.automatic)tableView.deleteRows(at:deletions.map({IndexPath(row:$0,section:0)}),with:.automatic)tableView.reloadRows(at:modifications.map({IndexPath(row:$0,section:0)}),with:.automatic)tableView.endUpdates()breakcase.error(leterror):// handle errorbreak}}funcinsertItem()throws{// Perform an interface-driven write on the main thread:collection.realm!.beginWrite()collection.insert(Item(),at:0)// And mirror it instantly in the UItableView.insertRows(at:[IndexPath(row:0,section:0)],with:.automatic)// Making sure the change notification doesn't apply the change a second timetrycollection.realm!.commitWrite(withoutNotifying:[token])}

Key-Value Observation

Realm objects are Key-Value Observing compliant for most properties. Almost all managed (non-ignored) properties on your Object subclasses are KVO-compliant, along with the invalidated property on Object and List. (LinkingObjects properties can’t be observed using KVO.)

Observing properties of unmanaged instances of Object subclasses works just like with any other dynamic property, but note that you cannot add an object to a Realm (with realm.add(obj) or other similar methods) while it has any registered observers.

Observing properties of managed objects (those previously added to a Realm) works a little differently. With managed objects, there are three times when the value of a property may change: when you directly assign to it; when you call realm.refresh() or the Realm is automatically refreshed after a write transaction is committed on a different thread; and when you call realm.beginWrite() after changes on a different thread which have not been picked up by a refresh on the current thread.

In the latter two cases, all of the changes made in the write transaction(s) on another thread will be applied at once, and KVO notifications will all be sent at once. Any intermediate steps are discarded, so if in the write transaction you incremented a property from one to ten, on the main thread you’ll get a single notification of a change directly from one to ten. Because properties can change in value when not in a write transaction or even as part of beginning a write transaction, trying to modify managed Realm objects from within observeValueForKeyPath(_:ofObject:change:context:) is not recommended.

Unlike NSMutableArray properties, observing changes made to List properties does not require using mutableArrayValueForKey(_:), although that is supported for compatibility with code not written with Realm in mind. Instead, you can simply call the modification methods on List directly, and anyone observing the property it is stored in will be notified. List properties do not need to be marked as dynamic to be observable, unlike normal properties.

Migrations

When working with any database, it is likely your data model will change over time. Since data models in Realm are defined as standard Swift classes, making model changes is as easy as changing any other Swift class. For example, suppose we have the following Person model:

We want to update the data model to require a fullName property, rather than separate first and last names. To do this, we simply change the object interface to the following:

classPerson:Object{dynamicvarfullName=""dynamicvarage=0}

At this point if you had saved any data with the previous model version, there will be a mismatch between what Realm sees defined in code and the data Realm sees on disk. When this occurs, an exception will be thrown when you try to open the existing file unless you run a migration.

Note that default property values aren’t applied to new objects or new properties on existing objects during migrations. We consider this to be a bug and are tracking it as #1793.

Performing a Migration

Defining Migrations

You define a migration and the associated schema version by setting Realm.Configuration.schemaVersion and Realm.Configuration.migrationBlock. Your migration block provides all the logic for converting data models from previous schemas to the new schema. When creating a Realm with this configuration, the migration block will be applied to update the Realm to the given schema version if a migration is needed.

For example, suppose we want to migrate the Person model declared earlier. The minimal necessary migration block would be the following:

// Inside your application(application:didFinishLaunchingWithOptions:)letconfig=Realm.Configuration(// Set the new schema version. This must be greater than the previously used// version (if you've never set a schema version before, the version is 0).schemaVersion:1,// Set the block which will be called automatically when opening a Realm with// a schema version lower than the one set abovemigrationBlock:{migration,oldSchemaVersionin// We haven’t migrated anything yet, so oldSchemaVersion == 0if(oldSchemaVersion<1){// Nothing to do!// Realm will automatically detect new properties and removed properties// And will update the schema on disk automatically}})// Tell Realm to use this new configuration object for the default RealmRealm.Configuration.defaultConfiguration=config// Now that we've told Realm how to handle the schema change, opening the file// will automatically perform the migrationletrealm=try!Realm()

At the very minimum all we need to do is to update the version with an empty block to indicate that the schema has been upgraded (automatically) by Realm.

Updating Values

While this is the minimum acceptable migration, we probably want to use this block to populate any new properties (in this case fullName) with something meaningful. Within the migration block we can call Migration().enumerateObjects(ofType: _:_:) to enumerate each Object of a certain type, and apply any necessary migration logic. Notice how for each enumeration the existing Object instance is accessed via an oldObject variable and the updated instance is accessed via newObject:

// Inside your application(application:didFinishLaunchingWithOptions:)Realm.Configuration.defaultConfiguration=Realm.Configuration(schemaVersion:1,migrationBlock:{migration,oldSchemaVersioninif(oldSchemaVersion<1){// The enumerateObjects(ofType:_:) method iterates// over every Person object stored in the Realm filemigration.enumerateObjects(ofType:Person.className()){oldObject,newObjectin// combine name fields into a single fieldletfirstName=oldObject!["firstName"]as!StringletlastName=oldObject!["lastName"]as!StringnewObject!["fullName"]="\(firstName)\(lastName)"}}})

Once the migration is successfully completed, the Realm and all of its objects can be accessed as usual by your app.

Renaming Properties

Renaming the property on a class as part of a migration is more efficient than copying values and preserves relationships rather than duplicating them.

To rename a property during a migration, make sure that your new models have a property with the new name and don’t have a property with the old name.

If the new property has different nullability or indexing settings, those will be applied during the rename operation.

Realm.Configuration.defaultConfiguration=Realm.Configuration(schemaVersion:2,migrationBlock:{migration,oldSchemaVersionin// The enumerateObjects:block: method iterates// over every 'Person' object stored in the Realm filemigration.enumerateObjects(ofType:Person.className()){oldObject,newObjectin// Add the `fullName` property only to Realms with a schema version of 0ifoldSchemaVersion<1{letfirstName=oldObject!["firstName"]as!StringletlastName=oldObject!["lastName"]as!StringnewObject!["fullName"]="\(firstName)\(lastName)"}// Add the `email` property to Realms with a schema version of 0 or 1ifoldSchemaVersion<2{newObject!["email"]=""}}})// Realm will automatically perform the migration and opening the Realm will succeedletrealm=try!Realm()

For a more complete look at the implementation of a data schema migration, check out our migration sample app.

Linear Migrations

Suppose we have two users for our app: JP and Tim. JP updates the app very often, but Tim happens to skip a few versions. It’s likely that JP has seen every new version of our app, and every schema upgrade in order: he downloaded a version of the app that took him from v0 to v1, and later another update that took him from v1 to v2. In contrast, it’s possible that Tim might download an update of the app that will need to take him from v0 to v2 immediately. Structuring your migration blocks with non-nestedif (oldSchemaVersion < X) calls ensures that they will see all necessary upgrades, no matter which schema version they start from.

Another scenario may arise in the case of users who skipped versions of your app. If you delete a property email at version 2 and re-introduce it at version 3, and a user jumps from version 1 to version 3, Realm will not be able to automatically detect the deletion of the email property, as there will be no mismatch between the schema on disk and the schema in the code for that property. This will lead to Tim’s Person object having a v3 address property that has the contents of the v1 address property. This may not be a problem, unless you changed the internal storage representation of that property between v1 and v3 (say, went from an ISO address representation to a custom one). To avoid this, we recommend you nil out the email property on the if (oldSchemaVersion < 3) statement, guaranteeing that all Realms upgraded to version 3 will have a correct dataset.

Encryption

Please take note of the Export Compliance section of our LICENSE, as it places restrictions against the usage of Realm if you are located in countries with an export restriction or embargo from the United States.

Realm supports encrypting the database file on disk with AES-256+SHA2 by supplying a 64-byte encryption key when creating a Realm.

// Generate a random encryption keyvarkey=Data(count:64)_=key.withUnsafeMutableBytes{bytesinSecRandomCopyBytes(kSecRandomDefault,64,bytes)}// Open the encrypted Realm fileletconfig=Realm.Configuration(encryptionKey:key)do{letrealm=tryRealm(configuration:config)// Use the Realm as normalletdogs=realm.objects(Dog.self).filter("name contains 'Fido'")}catchleterrorasNSError{// If the encryption key is wrong, `error` will say that it's an invalid databasefatalError("Error opening realm: \(error)")}

This makes it so that all of the data stored on disk is transparently encrypted and decrypted with AES-256 as needed, and verified with a SHA-2 HMAC. The same encryption key must be supplied every time you obtain a Realm instance.

See our encryption sample app for an end-to-end app that generates an encryption key, stores it securely in the keychain, and uses it to encrypt a Realm.

There is a small performance hit (typically less than 10% slower) when using encrypted Realms.

Testing and Debugging

Configuring the Default Realm

The easiest way to use and test Realm apps is to use the default Realm. To avoid overriding application data or leaking state between tests, you can simply set the default Realm to a new file for each test.

importXCTest// A base class which each of your Realm-using tests should inherit from rather// than directly from XCTestCaseclassTestCaseBase:XCTestCase{overridefuncsetUp(){super.setUp()// Use an in-memory Realm identified by the name of the current test.// This ensures that each test can't accidentally access or modify the data// from other tests or the application itself, and because they're in-memory,// there's nothing that needs to be cleaned up.Realm.Configuration.defaultConfiguration.inMemoryIdentifier=self.name}}

Injecting Realm Instances

Another way to test Realm-related code is to have all the methods you’d like to test accept a Realm instance as an argument, so that you can pass in different Realms when running the app and when testing it. For example, suppose your app has a method to GET a user profile from a JSON API and you’d like to test that the local profile is properly created:

Debugging

Debugging your Realm apps is easy, with the ability to view your app’s data in the Realm Studio.

Debugging apps using Realm’s Swift API must be done through the LLDB console.

Note that although the LLDB script installed via our Xcode Plugin allows inspecting the contents of your Realm variables in Xcode’s UI, this doesn’t yet work for Swift. Instead, those variables will show incorrect data. You should instead use LLDB’s po command to inspect the contents of data stored in a Realm.

Avoid Linking Realm and Tested Code in Test Targets

Since you’re using Realm as a dynamic framework, you’ll need to make sure your unit test target can find Realm. You can do this by adding the parent path to RealmSwift.framework to your unit test’s “Framework Search Paths”.

If your tests fail with an exception message "Object type 'YourObject' is not managed by the Realm", it’s likely because you’ve linked the Realm framework directly to your test target, which should not be done. Unlinking Realm from your test target should address that.

You should also make sure to only compile your model class files in your application or framework targets; never add them to your unit test targets. Otherwise, those classes will be duplicated when testing, which can lead to difficult to debug issues (see this issue for details).

You’ll need to make sure all the code you need to test is exposed to your unit test targets (use the public access modifier or @testable). See this Stack Overflow answer for details.

Current Limitations

Here’s a list of our most commonly hit limitations.

Please refer to our GitHub issues for a more comprehensive list of known issues.

General Limits

Realm aims to strike a balance between flexibility and performance. In order to accomplish this goal, realistic limits are imposed on various aspects of storing information in a Realm. For example:

Class names are limited to a maximum of 57 UTF8 characters.

Property names are limited to a maximum of 63 UTF8 characters.

NSData and String properties cannot hold data exceeding 16MB in size. To store larger amounts of data, either break it up into 16MB chunks or store it directly on the file system, storing paths to these files in the Realm. An exception will be thrown at runtime if your app attempts to store more than 16MB in a single property.

Any single Realm file cannot be larger than the amount of memory your application would be allowed to map in iOS — this changes per device, and depends on how fragmented the memory space is at that point in time (there is a radar open about this issue: rdar://17119975). If you need to store more data, you can map it over multiple Realm files.

Threads

Although Realm files can be accessed by multiple threads concurrently, you cannot directly pass Realms, Realm objects, queries, and results between threads. If you need to pass Realm objects between threads, you can use the ThreadSafeReference API. Read more about Realm’s threading.

Realm object setters and getters cannot be overriden

Since Realm overrides setters and getters to back properties directly by the underlying database, you cannot override them on your objects. A simple workaround is to create new, Realm-ignored properties, whose accessors can be overriden, and can call other setters/getters.

File size and tracking of intermediate versions

Realm read transaction lifetimes are tied to the memory lifetime of Realm instances. Avoid “pinning” old Realm transactions by using auto-refreshing Realms and wrapping all use of Realm APIs from background threads in explicit autorelease pools.

You should expect a Realm database to take less space on disk than an equivalent SQLite database. If your Realm file is much larger than you expect, it may be because you have a Realm that is referring to an older version of the data in the database.

In order to give you a consistent view of your data, Realm only updates the active version accessed at the start of a run loop iteration. This means that if you read some data from the Realm and then block the thread on a long-running operation while writing to the Realm on other threads, the version is never updated and Realm has to hold on to intermediate versions of the data which you may not actually need, resulting in the file size growing with each write. The extra space will eventually be reused by future writes, or may be compacted — for example by setting shouldCompactOnLaunch or calling Realm().writeCopyToPath(_:encryptionKey:).

To avoid this issue, you may call invalidate to tell Realm that you no longer need any of the objects that you’ve read from the Realm so far, which frees us from tracking intermediate versions of those objects. The Realm will update to the latest version the next time it is accessed.

You may also see this problem when accessing Realm using Grand Central Dispatch. This can happen when a Realm ends up in a dispatch queue’s autorelease pool as those pools may not be drained for some time after executing your code. The intermediate versions of data in the Realm file cannot be reused until the Realm object is deallocated. To avoid this issue, you should use an explicit autorelease pool when accessing a Realm from a dispatch queue.

Realm doesn’t have auto-incrementing properties

Realm doesn’t have a mechanism for thread-/process-safe auto-incrementing properties commonly used in other databases when generating primary keys. However, in most situations where a unique auto-generated value is desired, it isn’t necessary to have sequential, contiguous, integer IDs.

In these cases, a unique string primary key is typically sufficient. A common pattern is to set the default property value to NSUUID().UUIDString to generate unique string IDs.

Another common motivation for auto-incrementing properties is to preserve order of insertion. In some situations, this can be accomplished by appending objects to a List or by using a createdAt property with a default value of NSDate().

List and RealmOptional properties aren’t accessible from Objective‑C

If you need to access your Realm Swift models from Objective‑C, your List and RealmOptional properties will cause the auto-generated Objective‑C header (-Swift.h) to fail to compile because of the use of generics. You can work around this known Swift bug by annotating your List and RealmOptional properties as @nonobjc, which will hide them from the auto-generated Objective‑C header (-Swift.h).

Adding custom initializers to Object subclasses

When creating your model Object subclasses, you may sometimes want to add your own custom initialization methods for added convenience.

Due to some present limitations with Swift introspection, these methods cannot be designated initializers for the class. Instead, they need to be marked as convenience initializers using the Swift keyword of the same name:

classMyModel:Object{dynamicvarmyValue=""convenienceinit(myValue:String){self.init()//Please note this says 'self' and not 'super'self.myValue=myValue}}

Initializing Swift properties using Realm APIs

Your Swift app’s classes and structs might be defined with properties whose values are initialized using Realm APIs. For example:

classSomeSwiftType{letpersons=try!Realm().objects(Person.self)// ...}

If you do define types with such properties, you should note that you may run into problems if such initialization code is called before you have completed setting up your Realm configurations.

For example, if you set a migration block for the default Realm configuration in applicationDidFinishLaunching(), but you create an instance of SomeSwiftType before applicationDidFinishLaunching() has run and your Realm requires a migration, you’ll be accessing your Realm before it’s been correctly configured.

In order to avoid such issues you may choose to:

Defer instantiation of any type that eagerly initializes properties using Realm APIs until after your app has completed setting up its Realm configurations.

Define your properties using Swift’s lazy keyword. This allows you to safely instantiate such types at any time during your application’s lifecycle, as long as you do not attempt to access your lazy properties until after your app has set up its Realm configurations.

Only initialize your properties using Realm APIs that explicitly take in user-defined configurations. This way, you can be sure that the configuration values you are using have been set up properly before they are used to open Realms.

This includes iOS Extensions. To work around this, use unencrypted Realms, which can be shared across processes. You can make use of the Security and CommonCrypto system frameworks to encrypt and decrypt data stored in NSData properties on Realm objects.

We’re tracking lifting this limitation in both the Realm Cocoa issue tracker (#1693) and the Realm Core issue tracker (#1845).

Due to some overly-constrained checks in NSPredicate’s internal implementation, some of NSPredicate’s APIs are incompatible with Realm’s collection types. For example, -[NSPredicate evaluateWithObject:] will throw an exception when a subquery predicate attempts to iterate over a Realm collection.

If you need to work around this in your application, you can integrate the patch from PR #4770, invoking RLMWorkaroundRadar31252694() just once prior to performing any predicate evaluations.

Recipes

We’ve put together some recipes showing how to use Realm to accomplish a few specific tasks. We add more recipes regularly, so check back often. If there’s an example you’d like to see, please open an issue on GitHub.

Sync

The Realm Mobile Platform extends the capabilities of the Realm Mobile Database, enabling automatic synchronization of data across devices. To support this additional functionality, new types and methods are provided. These sync-specific APIs are a strictly additive extension to the Realm Mobile Platform API, and are covered below.

Users

The central object in the Realm Object Server is the Realm user (SyncUser) associated with a synchronized Realm. A SyncUser can be authenticated to a shared Realm via a username/password scheme, or through a number of third-party authentication methods.

Creating and logging in a user requires two things:

A URL of a Realm Object Server to connect to.

Credentials for an authentication mechanism that describes the user as appropriate for that mechanism (i.e., username/password, access key, etc).

Server URL

The authentication server URL is simply a URL representing the location of the Realm Object Server.

The username and password authentication is entirely managed by the Realm Object Server, giving you full control over your application’s user management. For other authentication methods, your application is responsible for logging into the external service and obtaining the authentication token.

Here are some examples of setting credentials with various providers.

Username/Password

Note that the factory method takes a register boolean argument that indicates whether a new user should be registered or an existing user should be logged in. An error will be thrown if your application tries to register a new user with the username of an existing user, or tries to log in a user that does not exist.

Google

letgoogleCredentials=SyncCredentials.google(token:"Google token")

Facebook

Apple CloudKit

Custom Authentication

The Realm Object Server supports the ability to use external authentication providers. This allow users to authenticate users against legacy databases or APIs, or integrate with providers that are not supported out-of-the-box by the Realm Object Server. For information on how to write a custom authentication provider, see that section of the Object Server manual.

Additional information can be passed to the custom credentials initializer as a third parameter. Please see the API reference for more information.

Authenticating the User

To create a user, call SyncUser.logIn(). This factory method will initialize the user, asynchronously log them in to the Realm Object Server, and then provide the user object for further use in a callback block if the login process is successful. If the login process fails for any reason, an error object will be passed into the callback instead.

SyncUser.logIn(with:credentials,server:serverURL){user,errorinifletuser=user{// can now open a synchronized Realm with this user}elseifleterror=error{// handle error}}

The Realm Mobile Platform allows an application to support multiple users at the same time.

For example, consider an email client app that supports connecting to multiple email accounts. Multiple users (one for each email account) can be authenticated at any given time, with all active users being available via SyncUser.all().

Logging Out

To log a user out of their account, call SyncUser.logOut(). Any pending local changes will continue to be uploaded until the Realm Object Server has been fully synchronized. Then, all of their local synced Realms will be deleted from their device on next app launch.

Working with Users

The current method will retrieve the current user, the last user who logged in and whose credentials have not expired. The method returns nil if no current user exists. An exception will be thrown if more than one logged-in user exists.

letuser=SyncUser.current!

If there are multiple users logged in, you can get a dictionary of user objects corresponding to them with all.

letallUsers=SyncUser.all

If no users are logged in, the dictionary returned will be empty.

Admin Users

Admin users are Realm Object Server users that have management-level access to all Realms on a ROS instance. Whether or not a user is an admin user is reflected by the SyncUser.isAdmin property, which reflects the user’s state at the time of its last successful login.

SyncUser.logIn(with:credentials,server:serverURL){user,errorinifletuser=user{// can now open a synchronized Realm with this user// true if the user is an administrator on the ROS instanceprint("User is admin: \(user.isAdmin)")}elseifleterror=error{// handle error}}

Opening a Synchronized Realm

Synced Realms are created using the same Realm.Configuration and factory methods that are used to create standalone Realms. Synced Realms must set the syncConfiguration property on their Realm.Configuration with a SyncConfiguration value. A Realm.Configuration, in turn, is constructed using a SyncUser and a Realm URL representing the location of the synced Realm on the Realm Object Server. The sync server URL should contain the tilde character (~), which will be transparently expanded to represent the user’s unique identifier. (For example, a realmURL of realms://acme.example.com/~/widgets might represent a shared “widgets” Realm.)

Notice: URLs cannot end with a “.realm” file extension. They should contain the main part of the name (e.g “widgets” above). Realm will create all the related files and folders to store the data.

The configuration values for a synced Realm cannot have an inMemoryIdentifier or fileURL configured. Setting either property will automatically nil out the syncConfiguration property. The framework is responsible for managing how synchronized Realms are cached or stored on disk.

The following example shows how a synced Realm might be opened given a user object and a Realm URL:

// Create the configurationletsyncServerURL=URL(string:"realm://localhost:9080/~/userRealm")!letconfig=Realm.Configuration(syncConfiguration:SyncConfiguration(user:user,realmURL:syncServerURL))// Open the remote Realmletrealm=try!Realm(configuration:config)// Any changes made to this Realm will be synced across all devices!

The tilde (~) character in a Realm URL expands to a unique user identifier for a Realm user. A “widgets” Realm each user has a copy of might be accessed as realm://acme.example.com/~/widgets; if a user has an ID of 5917268, then Realm will expand that URL to realm://acme.example.com/5917268/widgets. This allows your application logic to work with a URL representing the current user’s copy of a Realm all users access to, without needing to worry about managing the unique expanded representation of URLs for each individual user.

Sync Sessions

A synced Realm’s connection to the Realm Object Server is represented by a SyncSession object. Session objects representing Realms opened by a specific user can be retrieved from that user’s SyncUser object using the SyncUser.allSessions() or SyncUser.session(for:) APIs.

Basic Operations

The state of the underlying session can be retrieved using the state property. This can be used to check whether the session is active, not connected to the server, or in an error state.

If the session is valid, the configuration property will contain a SyncConfiguration value that can be used to open another instance of the same Realm (for example, on a different thread).

Progress Notifications

Session objects allow your app to monitor the status of a session’s uploads to and downloads from the Realm Object Server by registering progress notification blocks on a session object.

Progress notification blocks will be invoked periodically by the synchronization subsystem on the runloop of the thread in which they were originally registered. If no runloop exists, one will be created. (Practically speaking, this means you can register these blocks on background queues in GCD and they will work fine.) As many blocks as needed can be registered on a session object simultaneously. Blocks can either be configured to report upload progress or download progress.

Each time a block is called, it will receive the current number of bytes already transferred, as well as the total number of transferrable bytes (defined as the number of bytes already transferred plus the number of bytes pending transfer).

When a block is registered, the registration method returns a token object. The stop() method can be called on the token to stop notifications for that particular block. If the block has already been deregistered, calling the stop method does nothing. Note that the registration method might return a nil token if the notification block will never run again (for example, because the session was already in a fatal error state, or there is no further progress to report).

There are two types of blocks. Blocks can be configured to report indefinitely. These blocks will remain active unless explicitly stopped by the user and will always report the most up-to-date number of transferrable bytes. This type of block could be used to control a network indicator UI that, for example, changes color or appears only when uploads or downloads are actively taking place.

letsession=SyncUser.current!.session(for:realmURL)!lettoken=session.addProgressNotification(for:.download,mode:.reportIndefinitely){progressinifprogress.isTransferComplete{hideActivityIndicator()}else{showActivityIndicator()}}// Much later...token?.stop()

Blocks can also be configured to report progress for currently outstanding work. These blocks capture the number of transferrable bytes at the moment they are registered and always report progress relative to that value. Once the number of transferred bytes reaches or exceeds that initial value, the block will automatically unregister itself. This type of block could, for example, be used to control a progress bar that tracks the progress of an initial download of a synced Realm when a user signs in, letting them know how long it is before their local copy is up-to-date.

Access Control

The Realm Mobile Platform provides flexible access control mechanisms to specify which users are allowed to sync against which Realm files. This can be used, for example, to create collaborative apps where multiple users write to the same Realm. It can also be used to share data in a publisher/subscriber scenario where a single writing user shares data with many users with read permissions.

There are three levels that control the access (permissions) a user has to a given Realm:

mayRead indicates that the user is allowed to read from the Realm,

mayWrite indicates that the user is allowed to write to the Realm,

mayManage indicates that the user is allowed to change the permissions for the Realm.

Unless permissions are explicitly modified, only the owner of a Realm can access it. The only exception is administrator users: they are always granted all permissions to all Realms on the server.

Write-only permissions (i.e., mayWrite set without mayRead) are not currently supported.

Please refer to the general Realm Object Server documentation on Access Control to learn more about access control.

Retrieving Permissions

To get all the Realms a user has access to, along with the level of access for each Realm, use the SyncUser.retrievePermissions(...) method.

Modifying Permissions

Modifying the access control settings for a Realm file is performed through one of two means: applying/revoking permission values and offer/response objects.

Granting Permissions

Permission values can be applied (i.e. granted) to other users in order to directly increase or decrease their access to a Realm.

letpermission=SyncPermissionValue(realmPath:realmPath,// The remote Realm path on which to apply the changesuserID:anotherUserID,// The user ID for which these permission changes should be appliedaccessLevel:.write)// The access level to be granteduser.applyPermission(permission){errorinifleterror=error{// handle errorreturn}// permission was successfully applied}

To apply the permission changes for all Realms managed by the user, specify a realmPath value of *. To apply the permission changes for all users authorized with the Object Server, specify a userID value of *.

Revoking Permissions

Revoking permissions can either be done by granting a permission value with an access level of .none or by passing a permission value with any level to SyncUser.revokePermission(...). Both methods are identical.

PermissionOffer/Response

The SyncPermissionOffer and SyncPermissionOfferResponse classes allow you to share Realms between users, all from the client APIs – no server code is necessary.

Permission offers can be created and consumed by writing to the Management Realm. The Management Realm can be written to or read from just like a regular synchronized Realm. However, the Realm Object Server is specifically designed to react to changes to this Realm. Permission Change objects can be added to this Realm to modify the access control settings of a Realm file.

To obtain the Management Realm for a given user, call the SyncUser.managementRealm() method.

Sharing a Realm using permission offers involves following these steps:

Create a SyncPermissionOffer object in the sharing user’s management Realm.

Wait for the offer to be synced and processed by the Realm Object Server, which will populate the token property of the offer object.

Send the token to another user via any method.

The receiver creates a SyncPermissionOfferResponse in their management Realm.

Wait for the offer response to be synced and processed by the server, which will populate the realmUrl property of the response object.

The receiving user can now access the shared Realm at the URL.

letshareOffer=SyncPermissionOffer(realmURL:realmURL,expiresAt:nil,mayRead:true,mayWrite:true,mayManage:false)// add to management RealmtrymanagementRealm.write{managementRealm.add(shareOffer)}// wait for the offer to be processedletshareOfferNotificationToken=shareOffer.addNotificationBlock{_inguardshareOffer.status==.success,lettoken=shareOffer.tokenelse{return}// send `token` to the other user}

Similarly to permission value models, arguments control the read, write, and manage access for the Realm at the supplied realmURL. The expiresAt argument controls when the token will no longer be consumable. If you don’t pass a value to expiresAt, or pass nil, the offer will never expire. Note that users who have processed the offer token will not lose access after it expires.

Once another user has obtained the token, they can consume it and create a SyncPermissionOfferResponse object:

letresponse=SyncPermissionOfferResponse(token:token)trymanagementRealm.write{managementRealm.add(response)}// Wait for server to processletacceptShareNotificationToken=response.addNotificationBlock{_inguardresponse.status==.success,letrealmURL=response.realmUrlelse{return}// User can now access Realm at `realmURL`}

Permissions granted by SyncPermissionOffer are additive: if a user already has write access and accepts an offer granting read permissions, they will not lose their write access.

A permission offer can be revoked by deleting the SyncPermissionOffer object from the management Realm, or by setting its expiresAt property to a date in the past. This will prevent new users from accepting the offer, but will not revoke permissions of users who had consumed it prior to that.

Logging

The synchronization subsystem supports a number of logging levels, useful while developing an app. These can be selected by setting the logLevel property on the SyncManager singleton to the desired verbosity:

SyncManager.shared.logLevel=.off

The logging level must be set before any synced Realms are opened. Changing it after the first synced Realm is opened will have no effect.

Error reporting

Certain sync-related APIs perform asynchronous operations that may fail. These APIs take completion blocks which accept an error parameter; if the error parameter is passed in the operation failed. The error can be checked for more detail.

It is strongly recommended to also set an error handler on the SyncManager singleton. Errors involving the global synchronization subsystem or specific sessions (which represent Realms opened for synchronization with the server) will be reported through this error handler. When errors occur, the error handler will be called with an object representing the error, as well as a SyncSession object representing the session the error occurred on (if applicable).

Errors

In Swift 2.x, SyncError is instead an enum which describes various error codes. Work with the underlying NSError instead.

Client Reset

If a Realm Object Server crashes and must be restored from a backup, there is a possibility that an app might need to carry out a client reset on a given synced Realm. This will happen if the local version of the Realm in question is greater than the version of that same Realm on the server (for example, if the application made changes after the Realm Object Server was backed up, but those changes weren’t synced back to the server before it crashed and had to be restored).

The client reset procedure is as follows: a backup copy of the local Realm file is made, and then the Realm files are deleted. The next time the app connects to the Realm Object Server and opens that Realm, a fresh copy will be downloaded. Changes that were made after the Realm Object Server was backed up but weren’t synced back to the server will be preserved in the backup copy of the Realm, but will not be present when the Realm is re-downloaded.

The need for a client reset is indicated by an error sent to the SyncManager error handler. This error will be denoted by the code .clientResetError.

The error object will also contain two values: the location of the backup copy of the Realm file once the client reset process is carried out, and an opaque block that takes no arguments which can be called to initiate the client reset process.

If the block is called to manually initiate the client reset process, all instances of the Realm in question must first be invalidated and destroyed before the block is invoked. Note that a Realm might not be fully invalidated, even if all references to it are nil’ed out, until the autorelease pool containing it is drained. However, doing so allows the Realm to be immediately re-opened after the client reset process is complete, allowing syncing to resume.

If the block is not called, the client reset process will automatically take place after the next time the app is launched, upon first accessing the SyncManager singleton. It is the app’s responsibility to persist the location of the backup copy if needed, so that the backup copy can be found later.

A Realm which needs to be reset can still be written to and read from, but no subsequent changes will be synced to the server until the client reset is complete and the Realm is re-downloaded. It is extremely important that your application listen for client reset errors and, at the very least, make provisions to save user data created or modified after a client reset is triggered so it can later be written back to the re-downloaded copy of the Realm.

The backup copy file path and reset initiation block can be obtained by calling SyncError.clientResetInfo() on the error object. Note that the Swift 2.x version of this API is a class method which must be passed the NSError.

The following example shows how the client reset APIs might be used to carry out a client reset:

For more information about how the Realm Object Server handles client reset, please refer to our server documentation.

Syncing Migrations

Migrations are applied automatically to synced Realms, with some limitations and caveats:

Additive changes, such as adding a class or adding a property to an existing class, are applied automatically.

Removing a property from a schema will not delete the field from the database, but rather instruct Realm to ignore that property. New objects will continue be created with those properties, but they will be set to null. Non-nullable fields will be set to appropriate zero/empty values: 0 for numeric fields, an empty string for string properties, and so on.

Custom migration blocks cannot be invoked on synced Realm migrations, and supplying one will throw an exception.

Destructive changes–that is, changes to a Realm schema that require changes to be made to code that interacts with that Realm–are not directly supported. This includes changes to property types that keep the same name (e.g., changing from a nullable string to a non-nullable string), changing a primary key, or changing a field from optional to required (or vice-versa).

Custom migrations can be applied to synced Realms by writing a notification handler on the client side to make the changes, or as a JavaScript function on the server using the Node.js SDK (if you are using an edition of Object Serve that supports it). However, if the migration makes a destructive change, the Realm will stop syncing with ROS, producing a Bad changeset received error.

If you have destructive changes to apply in a synced Realm migration, instead create a new synced Realm with the new schema, and create a migration function which listens for changes on the old Realm and copies values to the new Realm. As with the non-destructive migration, this can be either code on the client side in the new version of the app (with the new schema version), or Node.js code on the server side.

Converting Local Realms to Synced Realms

Automatic conversions from local (non-synced) Realms to synced Realms are currently not supported. We plan to add support for this use case in the future.

If you have a local Realm that you wish to convert into a synced Realm, you must open a new synced Realm and then manually copy the objects from the local Realm into the synced Realm.

Conflict Resolution

FAQ

How big is the Realm library?

Realm should only add around 5 to 8 MB to your app’s download size. The releases we distribute are significantly larger because they include support for the iOS, watchOS and tvOS simulators, some debug symbols, and bitcode, all of which are stripped by the App Store automatically when apps are downloaded.

Is Realm open source?

Yes! Realm’s internal C++ storage engine and the language SDKs over it are entirely open source and licensed under Apache 2.0.

Realm also optionally includes a closed-source synchronization component, but that is not required to use Realm as an embedded database.

I see a network call to Mixpanel when I run my app, what is that?

Realm collects anonymous analytics when your app is run with a debugger attached, or when it runs in a simulator. These analytics are completely anonymous and help us improve the product by flagging which versions of Realm, iOS, OS X, or which language you target and which versions we can deprecate support for. This call does not run when your app is in production, or running on your user’s devices — only from inside your simulator or when a debugger is attached. You can see exactly what we collect and how we collect it, as well as the rationale for doing so, in our source code.

Why doesn’t Realm support Swift structs as models?

There are a number of reasons why Realm doesn’t currently support structs as models.

Most importantly, Realm is designed around “live” objects, a concept which is fundamentally incompatible with value type structs. There are a number of features provided by Realm which are incompatible with these semantics: liveness of data, reactiveness of APIs, low memory footprint of data, performance of operations, lazy and cheap access to partial data, lack of data serialization/deserialization, keeping potentially complex object graphs synchronized, etc.

That being said, it is sometimes useful to detach objects from their backing Realm. Unfortunately, this is more often needed to work around temporary limitations in our library rather than as an ideal design decision (such as thread-confinement). This is why we’ve worked hard to ensure that standalone/detached Realm objects behave exactly like plain old NSObjects. We support making “in-memory copies” of Realm objects by exposing an initializer that creates a standalone object via KVC copying of a persisted object’s properties. For example:

letstandaloneModelObject=MyModel(value:persistedModelObject)

Finally, we’d love to be able to offer an immutable, non-thread-confined, value-semantics Swift struct interface to Realm Objects. But Swift’s current language machinery, as well as some minor cosmetic limitations in our core database engine, prevent us from doing so without sacrificing all of the advantages of Realm’s “live” features outlined above. We’re working on addressing those internal shortcomings at the moment, and we’re hopeful that the property behaviors the Swift core team is currently working on (apple/swift#1297) will provide the machinery necessary for us to fully support Realm-backed Swift structs.

Troubleshooting

Crash Reporting

We encourage you to use a crash reporter in your application. Many Realm operations could potentially fail at runtime (like any other disk I/O), so collecting crash reports from your application will help identify areas where either you (or us) can improve error handling and fix crashing bugs.

Most commercial crash reporters have the option of collecting logs. We strongly encourage you to enable this feature. Realm logs metadata information (but no user data) when throwing exceptions and in irrecoverable situations, and these messages can help debug when things go wrong.

Reporting Realm Issues

If you’ve found an issue with Realm, please either file an issue on GitHub or email us at help@realm.io with as much information as possible for us to understand and reproduce your issue.

The following information is very useful to us:

Goals.

Expected results.

Actual results.

Steps to reproduce.

Code sample that highlights the issue (full Xcode projects that we can compile ourselves are ideal).

Reinstalling Via Dependency Managers

If you’ve installed Realm via CocoaPods or Carthage and you’re experiencing build errors, then it’s likely that you’re either using an unsupported version of that dependency manager, Realm’s integration into the project didn’t succeed, or part of your build tools have stale caches.

If that is the case, please try removing the folders the dependency manager created and installing again.

You can also try deleting derived data and cleaning the build folder in Xcode; this can fix issues caused by updating build tool versions or making changes to your project setup such as adding a new target, sharing dependencies across targets, etc.

To clean the build folder, hold down the ‘Option’ key while opening the ‘Product’ menu, then choose ‘Clean Build Folder…’. You can also type ‘Clean’ into the Xcode help search menu and select the ‘Clean Build Folder…’ menu item when it shows up in the search results.

CocoaPods

Realm can be installed via CocoaPods 0.39.0 or greater.

If you have troubles with your CocoaPods integration, it might help to reset the integration state. To achieve that simply run the following commands in Terminal out of your project directory:

You can also use cocoapods-deintegrate instead of deleting the Pods directory. With CocoaPods 1.0, this comes as preinstalled plugin. If you’re using an older version, you may consider installing it by gem install cocoapods-deintegrate. You can run it by pod deintegrate. That removes all traces of CocoaPods from your Xcode project.

Carthage

Realm can be installed via Carthage 0.9.2 or later.

To remove all Carthage-managed dependencies from your project, simply run the following commands in Terminal out of your project directory:

Realm Core Binary Fails to Download

When building Realm, part of the process includes downloading the core library as a static binary and integrating it into the realm-cocoa project.

It’s been reported that in certain instances, the core binary fails to download with the following error:

Downloading core failed. Please try again once you have an Internet connection.

This error can occur due to any of the following reasons:

Your IP address range is from a region that is on the list of United States embargoes. In order to comply with U.S. law, Realm has not been made available in that region. For more information, please see our license.

You are located in mainland China, and due to the country-wide firewall are not able to properly access CloudFlare or Amazon AWS S3 services at the moment. Please see this Realm-Cocoa Issue for more information.

Operating with low memory constraints

If you’d like to use Realm in a context with little available memory, such as a watchOS app or App Extension, we recommend that you specify the classes to be managed by a Realm explicitly in order to avoid a costly call to objc_copyClassList():